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Publication numberUS6292539 B1
Publication typeGrant
Application numberUS 09/086,386
Publication dateSep 18, 2001
Filing dateMay 29, 1998
Priority dateMay 29, 1998
Fee statusLapsed
Also published asCA2333518A1, CA2333518C, DE69931259D1, DE69931259T2, EP1093609A1, EP1093609A4, EP1093609B1, WO1999063427A1
Publication number086386, 09086386, US 6292539 B1, US 6292539B1, US-B1-6292539, US6292539 B1, US6292539B1
InventorsElliot Eichen, David L. Brooks
Original AssigneeVerizon Laboratories Inc.
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Method and apparatus for digital subscriber loop qualification
US 6292539 B1
Abstract
A system and methodology for qualifying a twisted pair copper loop for digital subscriber loop services are described. The system automatically queries telecommunications provider database records and/or requests measurements from network switching equipment or testing systems to obtain data regarding the twisted pair copper loop, such as loop length, electrical characteristics, and other loop topology characteristics such as wire gauge, the presence of load coils, and the presence of bridge taps. The system determines which digital subscriber loop services are available for the copper loop based on the combination of all data obtained. The system may be implemented in part as an expert system with a knowledge base of qualification rules used in the decision-making process.
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Claims(14)
We claim:
1. A method for qualifying a twisted pair loop for a digital subscriber service, the method comprising:
querying a service availability database and determining if the digital subscriber service is available on the loop;
querying a facilities database and determining: 1) if the loop is on a working pair, 2) whether a service currently on the loop is compatible with the digital subscriber service, and 3) what other services are active on other cable pairs that share a binder group with the loop;
querying a topology database and obtaining topology data corresponding to the loop;
combining all information retrieved from the service availability database, the facilities database, and the topology database; and
modeling a response of the loop using the combined information and a plurality of qualification rules.
2. The method of claim 1 further comprising:
determining whether the digital subscriber service is spectrally compatible with other services on the other cable pairs in the shared binder group.
3. The method of claim 1 further comprising:
performing measurements of the loop using a metallic loop electrical test system.
4. The method of claim 3 wherein the metallic loop electrical test system measures loop length.
5. The method of claim 3 wherein the metallic loop electrical test system measures loop capacitance.
6. The method of claim 3 wherein the metallic loop electrical test system measures longitudinal balance.
7. The method of claim 3 wherein the metallic loop electrical test system measures electrical ingress.
8. The method of claim 3 further comprising:
identifying differences between data received from the metallic loop electrical system and data retrieved from at least one of the service availability database, the facilities database, and the topology database, and
reconciling the differences using a series of predetermined rules.
9. The method of claim 1 further comprising:
determining how much bandwidth can be supported in both upstream and downstream directions on the loop.
10. A method for qualifying a twisted pair loop for a digital subscriber service, the method comprising:
querying a service availability database and determining if the digital subscriber service is available on the loop;
querying a facilities database and determining: 1) if the loop is on a working pair, 2) whether a service currently on the loop is compatible with the digital subscriber service, and 3) what other services are active on other cable pairs that share a binder group with the loop;
querying a topology database and obtaining topology data corresponding to the loop;
performing measurements of the loop using a metallic loop electrical test system;
identifying differences between data received from the metallic loop electrical system and data retrieved from at least one of the service availability database, the facilities database, and the topology database;
reconciling the differences using a series of predetermined rules;
combining all information retrieved from the service availability database, the facilities database, the topology database, and the measurements; and
modeling a response of the loop using the combined information and a plurality of qualification rules to output a list of digital subscriber services that the loop can support.
11. The method of claim 10 wherein the metallic loop electrical test system measures loop length.
12. The method of claim 10 wherein the metallic loop electrical test system measures loop capacitance.
13. The method of claim 10 wherein the metallic loop electrical test system measures longitudinal balance.
14. The method of claim 10 wherein the metallic loop electrical test system measures electrical ingress.
Description
BACKGROUND OF THE INVENTION

The present invention relates to digital subscriber loop technology and, more specifically, to the qualification of existing twisted pair copper loops for digital subscriber loop service.

Digital subscriber loop technology is the digital encoding of all information transmitted on the local loop, i.e., the connection between a customer's premises (home, office, etc.) and a telecommunications provider's central office serving the customer's premises. Most existing local loops in the United States and throughout the world are twisted pair copper loops, originally designed for analog service, or plain old telephone service (POTS). With digital subscriber loop technology, high speed access to the Internet, advanced telephony functions, and multimedia services is possible over the twisted pair copper access network. Digital subscriber systems can provide data from speeds of 64 kb/second in both upstream and downstream directions to over 10 Mb/second in a single direction. Digital subscriber loop technology, often referred to as xDSL where x stands for any of a number of letters, includes the following:

ADSL, Asymmetric Digital Subscriber Loop

VDSL, Very High-Speed Digital Subscriber Loop

HDSL, High Data Rate Digital Subscriber Loop

SDSL, Symmetric Digital Subscriber Loop

IDSL, ISDN-based Digital Subscriber Loop

RADSL, Rate Adaptive Digital Subscriber Loop

ISDN, Integrated Digital Service Network

Some of these digital subscriber loop technologies (e.g., HDSL, ISDN, and in particular ADSL) have been standardized by various standards bodies with respect to modulation format, bandwidth, and embedded operations channels, while others have not been standardized and are available from different vendors in a wide variety of modulation formats, upstream/downstream bandwidths, and operation channels.

As illustrated in FIG. 1, digital subscriber loop technology consists of two terminal endpoints (TEs) 10 and 20, which provide conversion, modulation, transmission, and reception of data, and copper loop 30 connecting TEs 10 and 20. TE 10 is typically owned and operated by the service provider, while TE 20 is typically at the customer's premises. In the United States, TE 20 is typically owned or rented by the customer, while in most other parts of the world TE 20 is typically owned and operated by the service provider. In addition, the digital subscriber loop topology can include terminal equipment, such as a repeater, between the two terminal endpoints to provide additional network flexibility or to boost signal strength and transmission distances. For example, FIG. 2 illustrates network terminal 70 in copper loop 60 between TEs 40 and 50.

Digital subscriber loop services, however, cannot be carried over all twisted pair copper loops that support POTS service. The various digital subscriber loop technologies have complex (real and imaginary) signal attenuation restrictions that depend upon downstream (to the customer) and upstream (from the customer) bandwidth, modulation format, and receiver sensitivity for a particular chip set used by a vendor terminal endpoint equipment. Signal attenuation itself depends on several factors, including the length and gauge of the copper wires contained in the loop, the environment in which the copper wires are placed (including temperature variations), and the quality of connections (e.g., splices and terminal connections) that attach the different sections of wire contained in a given loop. Digital subscriber loop technologies also have restrictions on loop topology, such as the position and number of bridge taps and load coils, and restrictions on services provided in adjacent copper pairs in the same binder group (i.e., a group of twisted pairs bundled together) because of crosstalk between pairs and overlapping frequency spectrums.

FIG. 3 illustrates a typical copper loop between central office (CO) 80 and terminal endpoint 82, made up of several different lengths of wire of different gauges spliced together. One leg of the loop terminates at terminal endpoint 82, while two other legs are unterminated, resulting in bridge taps 84 and 86. The loop in FIG. 3 also includes two load coils, 88 and 90, as well as cross connect 92.

As an example of loop topology requirements, a loop is restricted to less than approximately 5.25 km of 24 gauge wire when the digital service is provided at the rate of 1.5 Mb/second downstream and 80 kb/second upstream for a commonly available chip sent that uses carrierless amplitude phase (CAP) modulation for ADSL. For this modulation format and bandwidth allocation, if there is an analog carrier POTS service in the same wire binder group, the ADSL modulation will interfere with the analog carrier, effectively destroying the POTS service. Similarly, if there is a T1 carrier system in the same wire binder group, the T1 service will interfere with the ADSL modulation, nullifying the digital subscriber service, but typically not affecting the T1 service. The number of copper pairs and the potential for crosstalk in a binder group depends on the type and manufacturer of the copper cable.

Today, when a customer wishes to order a digital subscriber loop service, the local telecommunications service provider must determine whether the customer's existing twisted pair copper loop can support the requested digital subscriber loop service at the desired bandwidth. This can be a difficult and time-consuming task to perform manually because of the many restrictions on loop topology and services just described. All necessary data may not be available to a person trying to qualify a loop for digital subscriber loop services, particularly because telecommunications providers often have data in many different databases or stored in paper records. Even if data is available, data concerning outside plant information such as loop length and topology is often out of date. Also, certain metallic loop electrical data is not stored in a database and can only be determined by a measurement or test system.

It is desirable, therefore, to provide a system and methodology for determining which digital subscriber loop technologies can be supported by a particular twisted pair copper loop. It is more desirable to qualify a copper loop for digital subscriber loop services on the basis of real-time electrical measurements as well as records stored in telecommunications provider databases. It is even more desirable to provide an automated system for digital subscriber loop qualification that economically determines which digital subscriber loop technologies can be supported by a copper loop. It is also desirable to implement such a system as an expert system containing a knowledge base of rules.

SUMMARY OF THE INVENTION

The present invention satisfies those desires by providing a system and methodology for qualifying a twisted pair copper loop for digital subscriber loop services. The system automatically queries telecommunications provider database records and/or requests measurements from network switching equipment or testing systems to obtain information regarding the twisted pair copper loop in question. The system then determines which digital subscriber loop services are available for the copper loop based on the combination of all information obtained.

A method consistent with the present invention for qualifying a twisted loop pair for a digital subscriber service comprises the steps of receiving as input a unique identifier corresponding to the loop, determining a topology corresponding to the loop, and determining whether the loop meets topology restrictions of the digital subscriber service. Another method consistent with the present invention comprises the steps of receiving data corresponding to physical characteristics of the loop and applying a plurality of rules to the data to determine whether the loop is suitable for the digital subscriber service. Other methods consistent determine whether electrical characteristics of the loop meet restrictions of the digital subscriber service and whether services provided on other cable pairs in the same binder group with the loop are compatible with the digital subscriber service.

Systems are also provided for carrying out the methodologies of the present invention.

The advantages accruing to the present invention are numerous. A loop qualification system and method consistent with the present invention reduce the time for determining which digital subscriber loop services a particular copper loop supports from several hours to a few minutes. A system and method consistent with the present invention also provide a substantially more accurate result, in part because they use real-time electrical measurements to determine many topological characteristics of the copper loop.

The above desires, and other desires, features, and advantages of the present invention will be readily appreciated by one of ordinary skill in the art from the following detailed description of the preferred implementations when taken in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates digital subscriber loop technology connecting two terminal endpoints;

FIG. 2 illustrates digital subscriber loop technology with network terminal equipment between two terminal endpoints;

FIG. 3 illustrates a typical digital subscriber loop topology;

FIG. 4 illustrates the architecture of a loop qualification system consistent with the present invention; and

FIG. 5 is a flow chart of a method for qualifying loops consistent with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A system consistent with the present invention automatically qualifies twisted pair copper loops for digital subscriber loop services. Generally, a method for qualifying loops for digital subscriber loop services consistent with the present invention includes at least four types of qualification:

(1) Service Availability: Is the point at which the copper loop terminates equipped to provide the requested digital subscriber service?

(2) Length Qualification: Which digital subscriber loop services at which bandwidths can be provided given the length of the loop?

(3) Line Qualification: Is the loop physically suitable for use by a digital subscriber loop technology? Is the service currently provisioned on the loop compatible with digital subscriber loop service?

(4) Are the services provided on the other twisted pairs in the same binder group with the loop spectrally compatible with digital subscriber loop services?

In order to answer these loop qualification questions, a system consistent with the present invention combines results obtained from testing the copper loop, results from queries of telecommunication provider database records, and information regarding the transmission and receiver characteristics of the digital subscriber.

FIG. 4 illustrates the architecture of a system for qualifying loops consistent with the present invention, which may be implemented, for example, as an expert system using a conventional client-server architecture known in the art. The expert system is implemented in software residing on server 100 and performs loop qualification by combining input from a number of information sources with rules contained in knowledge base 105. Specifically, server 100 obtains information from service availability database 110, topology database 120, facilities database 130, and metallic electrical test system 140. Databases 110, 120, and 130, and test system 140 are typically owned and operated by the local telecommunications provider. It will be recognized by one skilled in the art that each database shown in FIG. 4 may actually consist of several smaller databases or, alternatively, that databases may be combined, since each telecommunications provider organizes its data into databases in different ways. Server 100 interfaces to the databases and test system via a suitable communications protocol such as IP or X.25, provided by interfaces 112, 122, 132, and 142. Server 100 additionally includes software handler modules for receiving and processing information obtained from databases 110, 120, and 130, and test system 140.

Server 100 also receives information and test results directly from central office switches in the local network, three of which are shown in FIG. 4 as switches 160, 170, and 180 for illustrative purposes. Server 100 is coupled to switch server 150, which is coupled to switch queues 164, 174, and 184, corresponding to switches 160, 170, and 180, respectively. Switch queues 164, 174, and 184 access data from switches 160, 170, and 180 via interfaces 162, 172, and 182, respectively. It will be recognized by one skilled in the art that switch server 150 need not be separate from server 100.

Consistent with the present invention, a user may access server 100 through either the graphical user interface of client 194, e.g., a World Wide Web-based client, or character interface 190, e.g., a VT100 character interface. Regardless of the interface used, a user will typically enter a unique number (e.g., a telephone directory number (TDN) or an IP address) or identifier (e.g., a circuit identifier) associated with the copper loop for which qualification is desired. A system consistent with the present invention also includes batch server 192, which allows qualification of numerous loops to be performed in batch, and database server 196 for storing results in results database 198.

FIG. 5 is a flow chart illustrating a method for qualifying loops for digital subscriber loop services consistent with the present invention. Consistent with an embodiment of the present invention, the method is performed by software residing on server 100. The process begins by receiving as input a unique identifier corresponding to the copper loop to be qualified for digital subscriber services (step 200). The unique identifier may be a telephone directory number (TDN) as shown in FIG. 5, or any other unique identifier such as an IP address or a circuit identifier. Also, server 100 may receive the identifier from any input source, including character interface 190 or web interface 194 (if a human user is accessing the system through an interface) and batch server 192 (if several qualification requests have been entered for batch processing). Most of the remaining steps in the process use the unique loop identifier to retrieve information regarding the loop.

Once receiving a loop identifier, the qualification process continues by determining whether digital subscriber loop services are available for the loop (step 210). Consistent with the present invention, the server makes this determination by querying service availability database 110 to determine whether the local telecommunications provider provides xDSL services from the office serving the customer's location. If xDSL service is not available, loop qualification terminates. If xDSL service is available, processing continues to step 220. In an alternate method consistent with the present invention, the server may choose to continue the loop qualification process although xDSL service is not available.

Next, the process determines whether the loop is on a working pair (step 220) by querying facilities database 130. Some measurement tests performed by a loop qualification method consistent with the present invention require that the loop be on a working pair. If the loop is not on a working pair, the server either terminates loop qualification (as shown in FIG. 5) or chooses to continue loop qualification, although not all tests will be available for the loop. Alternatively, the loop may be temporarily assigned to line equipment and a test number so that loop qualification may be performed.

If loop qualification continues, the server determines whether the current service on the loop is compatible with xDSL service (step 230). For example, in the United States the current service cannot be T1 or ISDN. Consistent with the present invention, the server performs this step by querying facilities database 130. As discussed above, it should be apparent to one skilled in the art that, although the queries in steps 220 and 230 both access databases with information regarding facilities, the facilities database shown in FIG. 4 (database 130) may consist of several smaller databases, so that the queries of steps 220 and 230 access two different, smaller databases. If the current service is not compatible, loop qualification ends. If the current service is compatible, then flow proceeds to several data collection steps. In an alternate method consistent with the present invention, the server may choose to continue the loop qualification process although the current service is not compatible with xDSL service.

A method consistent with the present invention performs some or all of data collection steps 240, 250, 260, and 270. These steps are not necessarily performed in a particular order, and some steps may be performed simultaneously. For example, FIG. 5 shows steps 240 and 250 being performed at the same time as steps 260 and 270. Each of these steps involves obtaining information about the loop to be qualified from a database or a test or measurement system in the network, and all of the information obtained is used as input to step 280, which applies a plurality of rules to the information to model the response of the network and determine which digital subscriber services are available on the loop.

In step 240, the server queries topology database 120 using the unique loop identifier (e.g., TDN or IP address) to obtain a variety of loop topology data. In particular, the server requests length and gauge of wire on the loop for each loop segment, cable type, the location of load coils on the loop, and the location and length of bridge taps on the loop. For example, the loop topology shown in FIG. 3 is an example of data that may be obtained from topology database 120. As described above, topology database 120 may consist of several smaller databases, each of which contains different information. Step 240 may also include a query of a separate database (not shown in FIG. 4) that stores recent measurements of the loop length. This data may be more accurate than a topology database operated by the telecommunications provider for storing many different types of loop topology data.

Referring again to FIG. 5, in step 250 the server queries facilities database 130 using the unique loop identifier to determine the services on other cable pairs in the same binder group as the loop to be qualified. This information will be used in step 280 to determine whether xDSL services are spectrally compatible with the services on the other cable pairs in the binder so that crosstalk will not degrade service quality.

In step 260, the server requests measurements from metallic electrical test system 140, which is a remote test system such as 4TEL, manufactured by Teradyne, Inc., or Mechanized Loop Test (MLT), manufactured by Lucent Technologies. Consistent with the present invention, the server requests a measure of loop length and/or loop capacitance, which can be converted to loop length using a known mathematical relationship. The server also requests measures of longitudinal balance and wideband and narrowband electrical ingress which will be used in step 280 to determine the suitability of the loop for digital subscriber loop services. As described earlier, tests in step 260 may not be performed if the loop is not on a working pair.

In step 270, the server requests a load coil detection measurement to determine if there are any load coils in the loop. This measurement can be performed at the end office switch at which the loop terminates (e.g., switch 160, 170, or 180 in FIG. 4) or by metallic electrical test system 140. If the server obtains the measurement from the switch, switch server 150 receives measurements from queues 164, 174, and 184, and controls server 100's access to switch measurements. Examples of load coil detection measurements known in the art are a swept frequency measurement and a time domain reflectometry measurement. As descirbed earlier, tests in step 270 may not be performed if the loop is not on a working pair.

All of the information obtained in steps 240, 250, 260, and 270 from database queries and test and measurement systems is input to step 280. Consistent with the present invention, in step 280 an expert system resident on server 100 combines the results of steps 240, 250, 260, and 270 with a plurality of qualification rules from knowledge base 105 and information on network equipment stored in a database (not shown for the sake of clarity) to model the response of the network for the various digital subscriber loop services available to the subscriber. The expert system also determines, for each of the available digital subscriber loop services (e.g., ADSL, VDSL, etc.), how much bandwidth can be supported in both upstream and downstream directions.

Consistent with the present invention, the qualification rules in knowledge base 105 are not limited to any particular set. The rules may range from the simple (e.g., a loop with one or more load coils does not qualify for a digital subscriber loop service) to the more complex (e.g., for a certain type of terminal equipment and a particular digital subscriber loop service with given upstream and downstream bandwidth, a combination of wire length and gauge limits can be calculated according to mathematical relationships to satisfy given signal attenuation and/or bit error rate requirements).

Consistent with the present invention, there may be a conflict between data retrieved from a database and data measured in real-time using a measurement system or test system. In such cases, knowledge base 105 can also include rules for reconciling the differences. For example, if data retrieved from a database is known not to have been updated recently, then a qualification method consistent with the present invention would rely on measured data, which may be more accurate.

The ultimate output of a system consistent with the present invention is a list of digital subscriber loop service packages that the loop can support. For a particular type of xDSL service (e.g., ADSL), there may be multiple packages, each of which defines a different class of service, including upstream and downstream bandwidth. For example, a loop may be able to support an ADSL package with downstream/upstream bit rates of 640k/272k, but the same loop may not support ADSL with bit rates of 640k/680k because of the loop length and topology. Alternatively, a system consistent with the present invention may determine whether a loop can support a specified digital subscriber loop service with given upstream and downstream bandwidths. In this case, the system user may enter the service type and bandwidth desired. In addition to simply listing qualified services, the system may provide the user with diagnostic information explaining why a particular decision was reached.

It will be apparent to those skilled in this art that various modifications and variations can be made to the loop qualification scheme of the present invention without departing from the spirit and scope of the invention. Other embodiments of the invention will be apparent to those skilled in this art from consideration of the specification and practice of the invention disclosed herein. In particular, the method is not limited to implementation in a client/server architecture or as an expert system. Nor is the invention limited to the user interfaces described. For example, a machine application program interface can provide access to the system from another system or as part of a larger provisioning system. A method consistent with the present invention can also be used to qualify loops for other services whose qualification requires access to database and/or real-time measurements. It is intended that the specification and examples be considered exemplary only, with the true scope and spirit of the invention being indicated by the following claims.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US5128619 *Sep 5, 1991Jul 7, 1992Bjork Roger ASystem and method of determining cable characteristics
US5181198Mar 12, 1991Jan 19, 1993Bell Communications Research, Inc.Coordinated transmission for two-pair digital subscriber lines
US5504896Dec 29, 1993Apr 2, 1996At&T Corp.Method and apparatus for controlling program sources in an interactive television system using hierarchies of finite state machines
US5864602 *Apr 28, 1997Jan 26, 1999Nynex Science & Technologies, Inc.Qualifying telephone line for digital transmission service
US5881130 *Sep 15, 1997Mar 9, 1999Teradyne, Inc.Fast and noise-insensitive load status detection
US5920609 *May 23, 1996Jul 6, 1999Wiltron CompanyFor a digital transmission system
US5966427 *Sep 30, 1997Oct 12, 1999Siemens InformationApparatus and method for troubleshooting internet protocol telephony networks
US5978449 *Dec 21, 1998Nov 2, 1999Nynex Science & Technologies, Inc.Qualifying telephone line for digital transmission service
US6058162 *Dec 5, 1997May 2, 2000Harris CorporationTesting of digital subscriber loops using multi-tone power ratio (MTPR) waveform
US6084946 *Nov 30, 1998Jul 4, 2000Bell Atlantic Network Services, Inc.Qualifying a telephone line for digital transmission service
US6091713 *Apr 13, 1998Jul 18, 2000Telcordia Technologies, Inc.Method and system for estimating the ability of a subscriber loop to support broadband services
US6177801 *Apr 21, 1999Jan 23, 2001Sunrise Telecom, Inc.Detection of bridge tap using frequency domain analysis
US6192109 *Dec 23, 1998Feb 20, 2001Globespan, Inc.Apparatus and method for improved DSL communication
US6215854 *Dec 7, 1998Apr 10, 2001Harris CorporationDigital signal processor-based telephone test set analyzing and displayed multiple signal parameter data for terminal mode and line monitor mode operation
US6215855 *Jan 21, 1999Apr 10, 2001Bell Atlantic Network Services, Inc.Loop certification and measurement for ADSL
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US6483870 *Dec 6, 1999Nov 19, 2002Cisco Technology, Inc.Data communication using a modifiable number of XDSL modems
US6496566 *Sep 29, 2000Dec 17, 2002Lucent Technologies Inc.Metallic testing of a subscriber loop that provides both voice and digital subscriber line services
US6532277 *Nov 12, 1999Mar 11, 2003Qwest Communications International Inc.Method for controlling DSL transmission power
US6566889 *Sep 4, 2001May 20, 2003Texas Instruments IncorporatedLine diagnostics for wireline modems
US6611579 *Mar 21, 2002Aug 26, 2003Verizon Laboratories Inc.Method for predicting and diagnosing trouble in a connection having a plurality of components
US6633545 *Jul 30, 1999Oct 14, 2003Cisco Technology, Inc.System and method for determining the data rate capacity of digital subscriber lines
US6643266 *Nov 24, 1999Nov 4, 2003Qwest Communications International Inc.Method for qualifying a loop for DSL service
US6671312Jan 19, 2001Dec 30, 2003Truecomm, Inc.Telecommunications line test method
US6687336 *Sep 30, 1999Feb 3, 2004Teradyne, Inc.Line qualification with neural networks
US6693992 *Jan 16, 2001Feb 17, 2004Mindspeed TechnologiesLine probe signal and method of use
US6741676 *Sep 30, 1999May 25, 2004Teradyne, Inc.Determining the physical structure of subscriber lines
US6744854Jan 9, 2002Jun 1, 2004Harris CorporationDetection of bridge taps by frequency domain reflectometry-based signal processing with precursor signal conditioning
US6760847 *Apr 13, 2000Jul 6, 2004Nortel Networks LimitedMethod for performing subscriber loop disturber recognition by comparing measured sample power spectral densities with a set of known power spectral densities
US6763087 *Mar 13, 2002Jul 13, 2004D-Link CorporationMobile VDSL signal detector
US6781386 *Aug 10, 2001Aug 24, 2004ThalesMethod and device for measuring a line attenuation
US6816575 *Feb 1, 2002Nov 9, 2004Harris CorporationSingle ended loop loss measurement by frequency domain reflectometry-based signal processing
US6819746 *Jul 10, 2000Nov 16, 2004Verizon Services Corp.Expert system for loop qualification of XDSL services
US6829330 *Apr 23, 2002Dec 7, 2004Aware, Inc.Systems and methods for loop characterization from double-ended measurements
US6865256 *Dec 21, 2000Mar 8, 2005AlcatelMethod and apparatus for determining properties of a transmission channel
US6865257May 8, 2003Mar 8, 2005Verizon Laboratories Inc.Method for resolving trouble in a connection having a plurality of components
US6870899 *Oct 4, 2002Mar 22, 2005Bellsouth Intellectual Property CorporationADSL loop qualification systems and methods
US6873684 *Aug 21, 2002Mar 29, 2005Bellsouth Intellectual Property Corp.System and method for estimating the capacity of a local loop to carry data
US6885730 *Jul 18, 2001Apr 26, 2005Paradyne CorporationSystem and method for subscriber loop testing
US6895081 *Apr 20, 1999May 17, 2005Teradyne, Inc.Predicting performance of telephone lines for data services
US6901137 *Sep 6, 2002May 31, 2005Teradyne, Inc.Detecting faults in subscriber telephone lines
US6914961 *Sep 30, 2002Jul 5, 2005Teradyne, Inc.Speed binning by neural network
US6934655 *Mar 16, 2001Aug 23, 2005Mindspeed Technologies, Inc.Method and apparatus for transmission line analysis
US6981186 *Jul 30, 2002Dec 27, 2005Ciena CorporationLoop diagnostic mode for ADSL modems
US6985444 *Oct 19, 2000Jan 10, 2006Teradyne, Inc.Binning of results from loop qualification tests
US7012991Jun 23, 2000Mar 14, 2006Teradyne, Inc.Qualifying telephone lines for data transmission
US7042983Oct 19, 2001May 9, 2006Teradyne, Inc.Method and apparatus for bridged tap impact analysis
US7071703Dec 6, 2004Jul 4, 2006Teradyne, Inc.Technique for estimation of a subscriber line insertion loss
US7079626 *Mar 5, 2003Jul 18, 2006Sbc Properties, L.P.System and method for imputing data into a database
US7263174Feb 18, 2005Aug 28, 2007Teradyne, Inc.Predicting performance of telephone lines for data services
US7286905Nov 16, 2005Oct 23, 2007At&T Knowledge Ventures, L.P.Method for calculating availability for line power systems
US7289604Apr 18, 2005Oct 30, 2007Paradyne CorporationSystem and method for subscriber loop testing
US7386039Sep 26, 2003Jun 10, 2008Tollgrade Communications, Inc.Method and apparatus for identifying faults in a broadband network
US7436935Dec 9, 2004Oct 14, 2008Tollgrade Communications, Inc.Qualifying telephone lines for data transmission
US7529348Jul 16, 2001May 5, 2009Tollgrade Communications, Inc.Method of performing insertion loss estimation
US7620154Dec 23, 2002Nov 17, 2009Cambron G KeithEquivalent working length determinative system for digital subscriber line circuits
US7627399Sep 11, 2007Dec 1, 2009At&T Intellectual Property I, L.P.Method for calculating availability for line power systems
US7664254Oct 2, 2002Feb 16, 2010AlcatelSystem and method for upstream power backoff for xDSL
US7698577May 2, 2006Apr 13, 2010Mindspeed Technologies, Inc.Communication system activation
US7720078 *Apr 1, 2005May 18, 2010Siemens AktiengesellschaftIndividual sending of messages to packet network subscribers
US7835431Jan 26, 2010Nov 16, 2010Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US7852910Jan 12, 2005Dec 14, 2010Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US7876815 *May 15, 2007Jan 25, 2011At&T Intellectual Property I, L.P.Methods and apparatus to qualify a wire-pair for a digital subscriber line (DSL) service
US7899582Oct 23, 2009Mar 1, 2011At&T Intellectual Property I, L.P.Method for calculating availability for line power systems
US7903790Jun 14, 2006Mar 8, 2011At&T Intellectual Property I, L.P.System and method for completing incomplete records in a database of twisted cable pair information
US8094703Oct 12, 2010Jan 10, 2012Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US8369394Nov 30, 2011Feb 5, 2013Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US8553750Jan 25, 2013Oct 8, 2013Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US8687680Oct 4, 2013Apr 1, 2014Aware, Inc.Systems and methods for loop length and bridged tap length determination of a transmission line
US8730824 *Aug 7, 2006May 20, 2014At&T Intellectual Property I, LpMethod and apparatus for managing services in a communication system
EP1300964A1 *Oct 3, 2001Apr 9, 2003Alcatel Alsthom Compagnie Generale D'electriciteA system and method for measuring crosstalk in XDSL networks
WO2003067858A1 *Jan 30, 2003Aug 14, 2003Harris CorpSignal ended lopp loss measurement by frequency domain reflectometry-based signal processing
Classifications
U.S. Classification379/1.04, 379/27.03, 379/27.01, 379/29.09
International ClassificationG06Q10/00, H04M3/22, H04M3/30, H04B3/46
Cooperative ClassificationH04M3/2209, H04M3/306, H04B3/46, G06Q10/06, H04M3/2227
European ClassificationG06Q10/06, H04B3/46, H04M3/30P2, H04M3/22F
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